Mechanism Analysis and Multi-Scale Protection Design of GaN HEMT Induced by High-Power Electromagnetic Pulse

• Published in: Micromachines (Basel) Vol. 13; no. 8; p. 1288
• Main Authors: Wang, Lei, Chai, Changchun, Zhao, Tianlong, Li, Fuxing, Qin, Yingshuo, Yang, Yintang
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.08.2022; MDPI
• Subjects: Analysis; Breakdown; Circuits; CMOS; Damage accumulation; damage effect; Electric fields; Electrodes; Electromagnetic interference; Electromagnetism; Electron avalanche; Electronic systems; Gallium nitrate; Gallium nitrides; GaN HEMT; High electron mobility transistors; high-power electromagnetic pulse; Liquors; Optimization; protection design; Semiconductor devices; Simulation; Yield point
• ISSN: 2072-666X; 2072-666X
• DOI: 10.3390/mi13081288

Currently, severe electromagnetic circumstances pose a serious threat to electronic systems. In this paper, the damage effects of a high-power electromagnetic pulse (EMP) on the GaN high-electron-mobility transistor (HEMT) were investigated in detail. The mechanism is presented by analyzing the variation in the internal distribution of multiple physical quantities in the device. The results reveal that the device damage was dominated by different thermal accumulation effects such as self-heating, avalanche breakdown and hot carrier emission during the action of the high-power EMP. Furthermore, a multi-scale protection design for the GaN HEMT against high-power electromagnetic interference (EMI) is presented and verified by a simulation study. The device structure optimization results demonstrate that the symmetrical structure, with the same distance from the gate to drain (Lgd) and gate to source (Lgs), possesses a higher damage threshold compared to the asymmetrical structure, and that a proper passivation layer, which enhances the breakdown characteristics, can improve the anti-EMI capability. The circuit optimization results present the influences of external components on the damage progress. The findings show that the resistive components which are in series at the source and gate will strengthen the capability of the device to withstand high-power EMP damage. All of the above conclusions are important for device reliability design using gallium nitride materials, especially when the device operates under severe electromagnetic circumstances.